This is a prime example of why biodiversity is so important, and in my opinion, why protecting it should be a top priority for all hackers.
Genetic information is code - code that has been written over millions of years. Nature is full of such wonderful programs and hacks. We don't yet know how to write even the simplest one, or even know about most of them. Yet, we're turning a blind eye to the current destruction of biodiversity and not thinking twice about it.
I don't understand why the Hacker News community isn't more interested in biodiversity loss, or why articles about climate change and biodiversity loss are not welcome here.
We're in the sixth mass extinction event, defined as a 75% loss of species, primarily caused so far by animal agriculture or, more precisely, by our food preferences. This situation is soon to be worsened by climate change.
But when someone mentions veganism around here, all those hackers flag his post to oblivion.
What makes all those javascript frameworks so important, and the code created by nature unimportant?
I feel helpless and very gloomy when I think about biodiversity loss and climate change. I even fast forward David Attenborough documentries when he talks about these things. Sometimes "its all going to hell but we are going in together" thought is more comforting than thinking about my own and everyone else apathy.
Thanks for making "code written by nature" comment. Knuth also agrees that bioinformatics has many more fantastic problems than computer science because its much much older.
I was in awe of planeria when I first saw it regenerating from its parts first time.
> But when someone mentions veganism around here, all those hackers flag his post to oblivion.
Veganism will never save us there.
It's because meat tastes good. That's literally all there is to why we aren't all vegan. Humans will not voluntarily give up one of the nice things they currently have access to and enjoy. Nobody cares about delayed indirect consequences on a planetary scale. Our brains aren't wired to think that way, since it provides no instant gratification.
If someone came up with a novel way to create a meat-like material that actually tastes as good, without involving inefficient animal farming, it will be a much more successful approach at solving this problem.
Yes, because for decades or longer, meat has been associated with affluence and a higher standard of living. There is no country in the world without meat & dairy subsidies.
On a finite planet with 8 billion people, to feed everyone the "western diet," we would need 2-5 such planets. It's simply not longer possible.
Veganism grows very fast, though. It's already starting to influence meat and dairy sales, enough to make some producers very nervous (wood milk ads, for example).
The most important thing I learned about changing people's minds is that you need to meet them where they are, not where you want them to be. This is not just for veganism, it's for any topic of interest. People want solutions that are convenient, and if you can give that to them while accomplishing your own goals in the process, that is what people will decide to use.
This is one reason why the rise of meat-like alternatives that nevertheless taste like meat are one of the most subersively impactful ways of turning someone vegan. I suspect once we as a species transition fully to lab grown meat, we will all basically be vegan. But the reason why so few people are vegan these days (out of the overall human population) because it is simply less convenient than eating meat, given that we like the taste of meat. There really is no alternative currently that still satiates people's demands for the taste of meat.
> once we as a species transition fully to lab grown meat
I wish... there are many obstacles to implementing that on the scale and timeline needed. I worry we don't have time to wait for that, while we already have plants that could sustain us completely and easily (82% of calories, 63% of proteins).
Well said. I had not made the parallel between genetic diversity and preservation of code, but now that you've put it like that it makes so much sense. I mean, I'd always cared about conservation, but this gives me yet another way to understand and explain its importance.
Genuinely curious, since almost all (all?) of your submissions to HN seem to involve the climate in some way: what do you do for a living? What causes you to gravitate towards these types of articles and discussions?
The Race to Save the Axolotl - when an axolotl loses a limb, it regrows, and nary a scar remains. But this incredible creature is on the brink of extinction.
The first robust count of axolotls in 1998 estimated that around 6,000 animals lived in each square kilometer ... in 2015, he only found 35 per square kilometer.
The axolotl is the world’s the oldest self-sustaining laboratory animal population.
But it is unknown how long researchers will still be able to work with the axolotl: Like many lab animals, they are highly inbred, which could threaten their survival. To measure how small a gene pool is, scientists use an “inbreeding coefficient:” identical twins have an inbreeding coefficient of 100, completely unrelated individuals a coefficient of zero. For healthy growth, a captive population should have a coefficient of 12.5 at maximum. The notoriously inbred Spanish Habsburgs had a coefficient of 20; the coefficient for axolotls is 35.
Axolotl are going extinct because the tiny extent of their natural habitat is underneath what is now Mexico City. There are 10 million people living on top of their native environment, veganism does nothing to address this.
The immediate jump to food preferences in this thread is strange, it's very evident that changing diet,
modes of transport and a plethora of other things we argue about doing is a rounding error compared to simply having one less child, overpopulation is the root cause of all this yet an incredibly taboo issue to discuss.
Well it was the guy I responded to who brought up veganisim as a solution in his top level post, but okay let's talk overpopulation. Axolotl have only ever been known to live in a few lakes which have been almost entirely obliterated by Mexico City, home to 10 million people (21 million if you count the whole metro area!) What exactly do you propose? Even if the population replacement rate in Mexico City were brought below 1, how many years would it take to depopulate the city? Short of forcing people out of the city at gunpoint (and to where, exactly?) how could you actually get the city depopulated in a reasonable amount of time to save the wild axolotl who might have a few years left at most? And how would this undo the habitat destruction which already occurred? How would you remove the structure of the city and restore the environment which it replaced decades+ ago?
Urbanization is often touted as the solution to habitat loss; concentrate people in high density urban areas to preserve the environment in the rest of the world. But in the case of Axolotl, they don't care for the rest of the world. They care about that specific piece of land that is under one of the largest metro areas in the world.
> And how would this undo the habitat destruction which already occurred? How would you remove the structure of the city and restore the environment which it replaced decades+ ago?
Not an expert by any means, but, as I understand it, Lake Texcoco National Park[1] is a fairly radical project (given the tendencies of urban politics) to move towards answering those questions.
> The main objective of this project is to reclaim the site to a green infrastructure in the valley of Mexico City. Rather than returning the area of an intact ecosystem from before the Spanish colonization, the key is to create a complete balance between infrastructure and nature.
This is already happening naturally without any sort of societal intervention. Who knew that people simply want to have fewer kids because life is better without them?
> Countries should work towards stabilising their populations first
The population growth is already starting to decline; for example, Europe is already experiencing a decline, the population growth in the US has recently flatlined.
World’s population is projected to nearly stop growing by the end of the century
> overpopulation is the root cause of all this yet an incredibly taboo issue to discuss
The root cause is overshoot. Climate change, resource depletion, deforestation, loss of biodiversity, pollution, overpopulation, soil erosion, and overfishing are all but symptoms of ecological overshoot.
How Compatible Are Western European Dietary Patterns to Climate Targets? Accounting for Uncertainty of Life Cycle Assessments by Applying a Probabilistic Approach
“Without concerted action, we found that the environmental impacts of the food system could increase by 50-90% by 2050 as a result of population growth and the rise of diets high in fats, sugars and meat,” he continued. “In that case, all planetary boundaries related to food production would be surpassed, some of them by more than twofold.”
The consumption of animal-sourced food products by humans is one of the most powerful negative forces affecting the conservation of terrestrial ecosystems and biological diversity.
We can either choose how to lower mean_individual_consumption, or wait for nature to reduce number_of_individuals forcibly. One way is better than the other.
Veganism would help solve climate change (15-25% co2, also methane and n20), deforestation, pollution, soil erosion and overfishing (5 things out of 7 causing overshoot of the carrying capacity of our environment).
> because the tiny extent of their natural habitat is underneath what is now Mexico City
I'm aware.
I was responding to the question why I'm interested in these topics, and I never suggested that axolots' problem could be solved by veganism.
You're right that veganism would not (probably) help in this specific case, but that was not the point of the comment you were reacting to.
I think it's a mix of groupthink and "someone else's problem". It's hard to break through an echo chamber and it's hard to accept something that inconveniences you. (I would assume the parts of the world where most of HN's audience resides are not going to be impacted by climate change as soon and as hard as many others.)
I do believe HN is full of intelligent and compassionate people. Perhaps it's compassion fatigue? (Too many horrible things happening, can I even make a difference through my individual actions?) Maybe we just needed you to make a good analogy, to illustrate the problem?
Veganism has nothing to do with biodiversity loss though.
Land clearing happens for ranching purposes, but is also happens for peanuts, coconut oil and all sorts of other products. Rice[1] is a cash crop associated with land clearing.
For example a practical sustainable diet for the world would be much more efficient if it included goat milk and meat, because goats can subsist off of marginal lands and foods which humans can't.
In terms of carbon sequestration and dealing w/ climate, it is clear that agricultural land use(especially land used for animal feed) is the largest barrier to ecosystem restoration. Potential for carbon sequestration is enormous (literally enough for the entire 1.5C carbon budget)
Yes yes you've got a big list of cherry-picked papers and pro-vegan PR which declares "meat bad".
Then just a quick dismissal of goats because it's devastating to your overall point if "vegan" isn't actually the solution and no answer at all to the existence of cash-cropping other then to say 'oh yeah it's probably animal feed'.
Really? Rice is animal feed? Give me a break. There's a reason no one takes vegans activists seriously - you're as loose with the truth and reality as any politician.
> Yes yes you've got a big list of cherry-picked papers
What's wrong with that? Show me a similar list of papers proving that animal agriculture is the solution for our problems, and I'll happily change my viewpoint. The problem is that no such independent and peer reviewed studies (can even) exist.
> Then just a quick dismissal of goats
Yeah, I think that grazing is extremely destructive for the ecosystems. Not when you've got a single goat or two, but at the scale yes. It's not a secret that previous civilizations had environmental pressures that contributed to their collapse, and overgrazing could be one of those reasons. A lot of those previous civilizations places are now deserts. Coincidence? I'd bet not :)
> existence of cash-cropping other then to say 'oh yeah it's probably animal feed'
We would need just a fraction of resources if it were not for pastures and the need for animal feed. It's not probably, it's for sure. Again, science.
> Really? Rice is animal feed?
I never said that. I'll give you this link/graph again:
I started for the environment, for the biodiversity and because the switch to plant based diets is a must for preserving the Earth for future generations (many reasons for that claim).
No words and social media comments can describe the sheer amount of destruction animal ag. is causing.
I learned to appreciate the moral aspect of it later. Carnism is a helluva drug.
Whenever morphogenesis comes up, especially with the usual "work from DNA and proteins up" approach, I feel obliged to mention Michael Levin. He also researches morphogenesis, except his approach is on a higher abstraction level. He manipulates the electrical network that cells use to communicate with each other to organize their work towards multicellular goals. Do watch his lectures, it's some really fascinating stuff. You don't need to touch genes at all to regrow limbs and organs. Neither do you need to operate on that low level to cure cancer. This whole "let's effect organism-level changes by observing and manipulating DNA and proteins" feels to me like "let's add a feature to a react web app by observing and modifying the behavior of individual transistors in the CPU". Doable given enough time, but you'd drown in complexity in the process.
I think that analogy is very apt- the fact that we have such a hard time understanding and predicting the outcomes of bioengineering/synthetic biology suggests that we are still missing huge parts of the picture of how life works.
It seems very likely to me that our views are too reductionist, and the much of the key information isn't even encoded at the level of DNA as previously assumed.
The cells multicellular organisms are constructed from are all shockingly similar... "cells" are basically a solved problem for this type of life, and somewhat frozen in their functionality because major changes would disrupt the larger systems that they make up.
What I said was a matter of opinion, I didn't quantify it in any way, so I'm not sure how you can say that, but I will elaborate more so you have something to really disagree with :-)
Sure, of course the different multicellular eukaryotes vary, but the diversity is very low compared to what we see across all life, look at Figure 1 here for example [1].
I am looking at it from the perspective of the structure of the metabolic network, as this is my area of research. There is a huge amount of diversity in the fundamental structures of metabolic networks, types of metabolites and enzymes produced, etc. across all life, but from that perspective the differences between one multicellular eukaryote and another are slight in comparison. Multicellular eukaryotes have evolved very different behaviors, shapes, sizes, etc. from a relatively conserved biochemistry. When taken out of the context of an organism in cell culture, the cells are similar enough that their behavior under diverse experimental conditions can be predicted by nearly identical metabolic models, whereas you would see nothing of the sort with distantly related bacteria- the metabolism can be massively rearranged.
You made a broad, almost dismissive generalization from, as it turns out now, a purely macroscopic view. It's like a physicist studying galaxy filaments saying "all galaxies are shockingly similar", because the filaments show more complex structures than individual galaxies.
Piling on; I emailed Michael Levin during lockdown and he replied with answers to some high level questions and a bit of documentation. Not sure what his pace is like these days but he seems open to sincere attempts at discourse.
Let's fund this instead of shitcoins, layers of indirection around POSIX.
I can't see any way that you could regrow a limb without "touching genes". And Levin doesn't say that in his video. At the very least, limb regrowth would require synthesis of many mRNA and their protein products, under the control of transcription factors.
Yes, but you don't do that. The cells themselves do it. You only trigger that mechanism and you do it by opening and closing specific ion channels in specific patterns.
The article is specifically about a difference in the mTOR protein, so in the end, a genetic difference. You will not trigger a limb regrowth in humans by opening and closing specific ion channels in our cells.
I seem to think you're interpreting that in a way that is not consistent with our current understanding of limb regrowth.
This is the paper: https://www.science.org/doi/10.1126/sciadv.abj2164 and it clearly states they treated a frog (xenopus, a common model organism), which does not normally regenerate when it's an adult. The paper clearly states that they treated with a set of factors that they believe induced a developmental plan- implemented by the transcription of DNA, translation of RNA, and expression of proteins. The initial treatment was removed, and the effect continued.
Also there's nothing about ion channels in this- the factors they used must have been actively transported- they bind to protein receptors.
I’ve watched at least half a dozen long presentations and interviews from dr levin and I’d say the previous commenter is essentially repeating it exactly how Levin describes it. To be fair it’s not exact. What I understood from the interviews is that they have been imaging bioelectrical activity in organisms during development and claim to have deciphered patterns associated with growth of certain structures. He talks about a certain ion channel drug (one used for epilepsy I believe) which they used to reproduce the bioelectric field previously observed and the organism grew a leg. Multiple legs actually, wherever they wanted. Also working eyes on arbitrary locations.
So from a high level they say they have figured out how to “speak” to cells in a sense and instruct them to start building certain structures. And they emphasize that they aren’t making any changes to the genome or manage any of the low level processes themselves.
Unless you can point me to some succinct papers or summaries, I'm going to continue with my believe that the dog wags the tail, not the other way around.
"Genes encode proteins and do not contain any other information": this is entirely false. It's well established that genes contain non-encoding regulatory regions (which happen to be very important for the process we're discusion).
All the cellular machinery ultimately derives from genetic regulation and protein expression. You can't make more of it wihtout making more mRNA, translating that to protein.
This is bio 101, basic stuff, unless I'm completely misreading what you're saying.
What? Michael Levin?
How about Dr. Robert O. Becker? I read about something similar in the 80s. Here's a link to one of his books, The Body Electric: https://a.co/d/fqzpaIv
Will we be able to genetically transfer this behaviour to, say, a mouse for testing, to see whether the mouse would gain the ability to regrow its limbs or tail?
Imagine if we can get to a world where the difference between not having health insurance and having insurance means either you wait for your body to naturally regrow a limb or your insurance covers a more quickly lab grown one.
Imagine a world where organ transplant wait lists aren't a thing.
Imagine a world where Ukrainian landmine victims are walking on new limbs.
We can have this, but instead our best minds are fucking around with optimizing web ads, or they're figuring out how to tweak assembly lines that shit out McDonald's Happy meal toys.
Something tells me that death is built-in feature of many nested systems in order to prevent stagnation / local minima or maxima. In the case of social humans, death prevents bad people from remaining alive forever, cementing in power structures and not providing the needed substrate for continual growth of a society.
I don't mean to ascribe intention to nature, but rather state that social systems which get far enough for its members to discuss it freely on the internet likely converge on this feature.
One could argue that eternal life unlocks the next phase of a civilization, but I am unconvinced that humanity is even properly equipped for the level of technology we have today, much less tomorrow.
I would rather a hundred bad people live than let one more good person die if we can help it.
> I am unconvinced that humanity is even properly equipped for the level of technology we have today, much less tomorrow.
If you had 1,000 years to figure everything out, you would be more than properly equipped. Instead we all have to operate with this arbitrary 80ish years to just barely figure anything out and then most of us die before we can do anything with the knowledge. It is a horrible and unfair system. Imagine if Einstein were still around today and was able to keep building on top of the knowledge he had before. Surely in that time he would have gotten things done that the vast majority of people could not begin to imagine.
> I would rather a hundred bad people live than let one more good person die if we can help it.
Why would you want that? Sounds like a terrible society to live in. Imagine if Einstein still existed, sure, but also imagine if a hundred serial killers or Hitlers still existed.
Can we? I think a necessary step towards this direction is a complete genetic model of the human body, which we haven’t even the ability to compute until very recently (if at all).
I feel like we need to solve the bioinformatics thing before we’re able to gcc new body parts. Which I think is incredibly solvable, though ofc it’ll take decades.
How specifically would you propose to reduce the rate of traumatic amputations in Ukraine? There are a wide variety of kinetic weapons being used beyond just landmines.
Most humans as they currently are may need 16 years to grow an adult size limb, but it doesn't need to be that way.
An interesting question would be how long does it take a baby to gain the mass of a limb?
Another interesting question would be how fast can an adult gain weight?
Another interesting question would be if it takes a person 18 years to reach 6' and 160lbs and then they stop growing, how long would it take them to grow another foot or two if they didn't stop growing?
> Imagine if we can get to a world where the difference between not having health insurance and having insurance means either you wait for your body to naturally regrow a limb or your insurance covers a more quickly lab grown one.
You are imagining a wonderful technological future where we can regrow limbs AND we still do not have universal health coverage. I think most of us like to imagine that by the time technology can regrow limbs, politics will have finally caught up to the rest of the developed world. Your better imagined future still includes people not having health coverage and for me that seems weird!
We currently live in a wonderful technological future where we can transplant organs AND we still do not have universal health coverage.
The future will be very much the same, and material inequality will very likely increase in the near future.
From a humanist perspective the best we can do is empower individuals with endogenous technology that minimizes their dependency on rent seekers and the innate ability to regenerate limbs and organs fits the bill nicely.
> Yes I'm trying to frame it in terms the audience of HN can understand.
> I'm not sure what's wrong with that.
What's wrong is that it's orthogonal to the problem, so it risks creating a pointless discussion about health insurance instead of focusing on the technology. The key problem is the ability to regrow limbs is not yet within our technological reach.
Having (or not) health insurance won't get you another pair of legs if you walk on a mine. Maybe you'll get very fancy prosthetics, but it will not be flesh and bone.
In a world where this is known technology, even if the costs may initially put it out of reach of people without insurance, should it just be a gene edit AND we have the ability to gene edit like we now have the ability to 3d print, the cat will be out of the bag, and it will be like people buying 3d printers to 3d print guns in countries where gun ownership is forbidden, or people ordering drugs on the dark web: it may be illegal, but people with addictions (or here, without legs) may not really care about the legality.
Or they will just do a road trip to Mexico, like how it is for dental work.
Health insurance is rarely the #1 issue: I think even Europeans do similar trips when they want something immediately instead of accepting long waitlines or some procedures not being officially available in their country. The only difference is they don't go to Mexico but to Turkey, the Balkans or Eastern Europe.
What we need is more technology, and fewer legal limitations, like how it was pointed out last week about how the FDA risk aversion costs human lives in a way that's impossible (or extremely hard) to measure.
We're very lucky the Trump administration (and a few others around the world) decided to bypass the regular vaccine safety process during operation warp speed: regardless of what you think about Covid vaccines, we now have mRNA vaccine technology, which is already being tested for many other things.
> Axolotls, they discovered, have an ultra-sensitive version of mTOR, a molecule that acts as an on-off switch for protein production. And, like survivalists who fill their basements with non-perishable food for hard times, axolotl cells stockpile messenger RNA molecules, which contain genetic instructions for producing proteins. The combination of an easily activated mTOR molecule and a repository of ready-to-use mRNAs means that after an injury, axolotl cells can quickly produce the proteins needed for tissue regeneration.
> Abstract: Temporal identity factors are sufficient to reprogram developmental competence of neural progenitors and shift cell fate output, but whether they can also reprogram the identity of terminally differentiated cells is unknown. To address this question, we designed a conditional gene expression system that allows rapid screening of potential reprogramming factors in mouse retinal glial cells combined with genetic lineage tracing. Using this assay, we found that coexpression of the early temporal identity transcription factors Ikzf1 and Ikzf4 is sufficient to directly convert Müller glial (MG) cells into cells that translocate to the outer nuclear layer (ONL), where photoreceptor cells normally reside. We name these “induced ONL (iONL)” cells. Using genetic lineage tracing, histological, immunohistochemical, and single-cell transcriptome and multiome analyses, we show that expression of Ikzf1/4 in MG in vivo, without retinal injury, mostly generates iONL cells that share molecular characteristics with bipolar cells, although a fraction of them stain for Rxrg, a cone photoreceptor marker. Furthermore, we show that coexpression of Ikzf1 and Ikzf4 can reprogram mouse embryonic fibroblasts to induced neurons in culture by rapidly remodeling chromatin and activating a neuronal gene expression program. This work uncovers general neuronal reprogramming properties for temporal identity factors in terminally differentiated cells.
>> Is it possible to produce or convert Müller glial cells with Nanotransfection (stroma reprogramming), too?
> A number of factors have been identified as the important regulators in Müller glial cell reprogramming. The early response of Müller glial cells upon acute retinal injury, such as the regulation in the exit from quiescent state, the initiation of reactive gliosis, and the re-entry of cell cycle of Müller glial cells, displays significant difference between mouse and zebrafish, which may be mediated by the diverse regulation of Notch and TGFβ (transforming growth factor-β) isoforms and different chromatin accessibility.
> In a paper published in Nature Materials, researchers from the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS) report the development of a new hydrogel ink infused with gelatin fibers that enables 3D printing of a functional heart ventricle that mimics beating like a human heart. They discovered the fiber-infused gel (FIG) ink allows heart muscle cells printed in the shape of a ventricle to align and beat in coordination like a human heart chamber.
> “People have been trying to replicate organ structures and functions to test drug safety and efficacy as a way of predicting what might happen in the clinical setting,” says Suji Choi, research associate at SEAS and first author on the paper. But until now, 3D printing techniques alone have not been able to achieve physiologically-relevant alignment of cardiomyocytes, the cells responsible for transmitting electrical signals in a coordinated fashion to contract heart muscle.
could someone with expertise in regenerative medicine kindly shed light on this quote, please?
quote:
"It was a 180-degree flip when we realized that when an axolotl loses a limb, it actually increases protein synthesis despite the energy cost," Barna said.
questions:
what is the conventional wisdom on how limb regeneration occurs w/o increasing protein synthesis?
inferring from other passages, it seems like conventional research focuses on mRNAs, not actual protein synthesis. why?
I don't think there was any conventional wisdom and on how limb regeneration occurs without increasing protein synthesis. Personally, I think the person who said that (Barna) is wrong/misinformed (even for a harvard professor!). They specifically meant protein synthesis is lower during stress response (of which limb regeneration is just one highly specialized variant), but we already know that's not true- in fact, whole extra stress-related proteins start being expressed which carry out special repair pathways. But maybe... if you count the overall protein synthesis amount, it seems like the cell would also shut down some non-essential functionality temporarily.
As for focusing on mRNA- biologists study where the light is, not where it isn't, and mRNA is incredibly easy to study compared to protein synthesis. It's much easier to just convert that mRNA back to DNA and sequence it and get loads of identity and abundance information.
Genetic information is code - code that has been written over millions of years. Nature is full of such wonderful programs and hacks. We don't yet know how to write even the simplest one, or even know about most of them. Yet, we're turning a blind eye to the current destruction of biodiversity and not thinking twice about it.
I don't understand why the Hacker News community isn't more interested in biodiversity loss, or why articles about climate change and biodiversity loss are not welcome here.
We're in the sixth mass extinction event, defined as a 75% loss of species, primarily caused so far by animal agriculture or, more precisely, by our food preferences. This situation is soon to be worsened by climate change.
But when someone mentions veganism around here, all those hackers flag his post to oblivion.
What makes all those javascript frameworks so important, and the code created by nature unimportant?